KR102540251B1 - Friction sets for railway braking systems - Google Patents

Abstract

A friction set (16) for a railway disc brake system (12) of a railway vehicle (10), said friction set (16) comprising:
- a shoe holder (3) comprising an accommodating slideway (4);
- a friction shoe (22) comprising a brake pad (7) and a profile shape (6) configured to slide into the receiving slide (4), said friction shoe (22) having a first face (71) of the friction shoe (22). A friction shoe (including a pneumatic conduit 9 connecting a first space E1 partitioned by ) to a second space E2 partitioned by a second surface 72 opposite the friction shoe 22. 22);
- at least one through hole (38) arranged in the shoe holder (3) and directed towards the pneumatic conduit (9); and
- a pneumatic joining ring (8) disposed within the pneumatic conduit (9) forming a pneumatic guide between the through hole (38) of the shoe holder (3) and the pneumatic conduit (9) of the friction shoe (22);

Description

Friction sets for railway braking systems

The present invention relates to railway vehicles. More specifically, the present invention relates to the braking of railway vehicles and in particular to friction sets for braking systems of railway vehicles. According to the present invention, it should be noted that any construction configured to roll on a rail is within the scope of the present invention. Thus, the present invention is equally applicable to, for example, trains, streetcars and metropolitan light rail.

Railroad vehicles, such as locomotives, passenger cars or wagons, usually include a braking system. The disc brake solution is one of many braking solutions. Thus, a braking system generally comprises a disc fixed to a wheel or axle of a railway vehicle. The braking system further includes a friction set, the friction set including a shoe holder supporting the friction shoe. A friction shoe generally includes a shoe holder and means for attaching to a brake pad. When the driver activates the braking system, the brake pads of the friction shoes come into contact with the disc and apply a braking force to the disc. Thus, by means of friction, the friction shoe brakes the disc fixed to the wheel or axle. In general, railway vehicles include two friction sets arranged on either side of the disc to press the disc from both sides, to clamp the disc or, in other words, to fit the disc.

The brake pad of the friction shoe generally contains a metal material such as cast iron, sintered material or composite material. Thus, when the brake pad of the friction shoe rubs against the disk, particles of material from the brake pad are released into the atmosphere around the friction set. Thus, the braking system emits air pollutants in the form of rather fine particles.

Therefore, in particular, by providing a blower supplied by a pump or a suction device near the ejection area of the particles coming out of the brake pad of the brake shoe, particles of the material released during braking are captured.

However, these devices operate in open spaces. In practice, the area of emission of particles from braking, in particular from brake pads, is not limited. This is why the yield or effectiveness of the blower or suction device is relatively low. In addition, it is difficult to integrate these devices into the structure of a rail vehicle.

It is an object of the present invention to provide a friction set that more effectively captures the particles emitted by brake pads and friction shoes during the braking cycle and is easily integrated into the railway vehicle structure.

It is an object of the present invention to provide a friction set that more effectively captures the particles emitted by brake pads and friction shoes during the braking cycle and is easily integrated into the railway vehicle structure.

To this end, according to the present invention, a friction set for a railway disc brake system of a railway vehicle moving in one or two directions, the friction set comprising:

- shoe holders including receiving slides;

- a friction shoe comprising a brake pad and a profile shape configured to slide into a receiving slide, the friction shoe comprising a first space defined by a first face of the friction shoe and a second space defined by a second opposite face of the friction shoe. a friction shoe comprising a pneumatic conduit connecting to the space;

- at least one through hole arranged in the shoe holder and directed towards the pneumatic conduit; and

- a pneumatic joint ring disposed in the pneumatic conduit forming a pneumatic guide between the through hole of the shoe holder and the pneumatic conduit of the friction shoe;

Accordingly, the friction shoe has a through hole disposed in the shoe holder and includes a pneumatic conduit for sucking in particles ejected by the brake shoe of the friction shoe during braking. Also, the pneumatic joint ring functions to guide the particles coming from the pneumatic conduit of the friction shoe by braking into the through hole of the shoe holder. The pneumatic joint ring thus functions to limit leaks that may occur from the pneumatic conduit. In particular, the pneumatic joint ring limits the amount of particles generated by braking and sliding within the gap located between the friction shoe and the shoe holder. Thus, the friction set according to the present invention functions to suck in more particles generated by braking with the same suction force. So it becomes more effective. Thus, the friction set according to the present invention can simply establish a pneumatic circuit for removing particles generated by braking.

Additionally, in various embodiments of the present invention, one and/or other of the following configurations may be used.

- Profile shape is dovetail.

- The pneumatic joint ring includes a flange and preferably a conical portion that rests on the bottom of the receiving slideway. Pneumatic guides can be simply molded with this device.

- It should be noted that more generally the part may be of any type of shape and in particular of any shape.

- The conical part is cylindrical.

- The height of the conical portion is comparable to the height of the dovetail profile shape, and with this configuration, particles generated by braking can be more effectively guided from the pneumatic conduit of the friction shoe to the through hole of the shoe holder.

- The receiving chute of the shoe holder is blind on one side. More specifically, the receiving chute has one closed end and one open end defining an opening for the removal and insertion of friction shoes. The friction shoes further include a detachable member for securing the friction shoes within the receiving chute so that the friction sets can be easily replaced if necessary, thereby facilitating maintenance of the friction sets.

- the friction shoe is formed by a first member and a second member, which will contact each other at the butting area of the first and second member leaving a passage between them to form a pneumatic conduit; It is configured to slide within the receiving slideway until

- the first and second members each form a half of the friction shoe; The passage left at the interface of the two friction shoes is formed in the center of the discharge area of particles discharged during braking; The intake of the particles emitted during braking is thus carried out in the same way regardless of the running direction of the railway vehicle; The behavior for the removal of particles emitted during braking is consequently simpler to model.

- The first and second members are juxtaposed in a direction in contact with the brake disc of the railway vehicle.

- the passage left at the interface of the first and second members is arranged in the middle part of the abutment zone; This involves simple fitting.

- the butt area is substantially defined by the butting plane; the first and second members are of similar length in the longitudinal direction of the shoe holder and the through hole has a center defining an axis coincident with or spaced less than 5 mm from the butting plane; The air behavior of the friction set is thus symmetrical, which is advantageous since the railway vehicle has two directions of movement.

- the friction set comprises a pneumatic connector mounted on the shoe holder, extending away from the friction shoe and pneumatically connected to the through hole; The pneumatic connector functions to direct particles coming from the pneumatic circuit formed by the through hole disposed in the shoe holder and the conduit of the friction shoe to the collecting member having the filter.

- the pneumatic connector is rotationally movable relative to the shoe holder about an axis orthogonal to the main plane of the shoe holder; The friction set can thus be easily integrated into the braking system of a rail vehicle; This mounting also allows for substantial amplitude in relative movement.

- The friction set includes a hose pneumatically connected to the through hole and extending away from the friction shoe.

- the friction set comprises a pump connected directly or otherwise to the hose and configured to generate a reduced pressure in the through hole; Accordingly, the friction set serves to suck in particles generated by braking through a pneumatic circuit formed by a pneumatic conduit of the friction shoe and a through hole arranged in the shoe holder.

According to the present invention, a railway disc brake system for one- or two-way moving railway vehicles is provided, comprising a disc fixed to an axle or wheel and two friction sets as described above disposed on either side of the disc. It can be.

Further, according to the present invention, there is provided a friction set for a railway disc brake system for a railway vehicle moving in one direction or two directions, characterized in that the friction set includes the following configuration.

- shoe holders including receiving chute;

- Friction shoes with profiled shapes for sliding into brake pads and receiving slides. The friction shoe includes a pneumatic conduit connecting a first space defined by a first face of the friction shoe to a second space defined by an opposite second face of the friction shoe.

- at least one through hole disposed in the shoe holder and threaded towards the pneumatic conduit; and

- a pneumatic connector pneumatically connected to the through hole, extending away from the friction shoe and mounted on the shoe holder for rotational movement relative to the shoe holder about an axis orthogonal to the main plane of the shoe holder.

This allows particles ejected during braking to reach the pneumatic conduit of the friction shoe and then to the through hole arranged in the shoe holder. Particles ejected during braking then reach the pneumatic connector. Thus, it is possible to connect the two by connecting the pneumatic connector to the system for withdrawing the brake particles, for example by means of a hose. In addition, since the pneumatic connector can be rotated about an axis orthogonal to the main plane of the shoe holder, the pneumatic connector can be easily placed in the railway vehicle.

Additionally, in various embodiments of the present invention, one and/or other of the following configurations may be used.

- Profile shape is dovetail.

- The friction set includes a hose pneumatically connected to the pneumatic connector and extending away from the friction shoe.

- The friction set is connected directly or indirectly to the hose and includes a pump configured to create a reduced pressure in the through hole.

- The receiving chute of the shoe holder is blocked. More specifically, the receiving chute has one closed end and one open end defining an opening for insertion and removal of friction shoes. The friction set further includes a detachable member for securing the friction shoe within the receiving chute.

- the friction shoe comprises a first member and a second member, when the first member and the second member are in contact with each other in the butting area of the first and second member leaving a passage therebetween to form a pneumatic conduit. It is configured to slide within the receiving slideway up to .

- each of the first and second members form one half of the friction shoe;

- The friction shoe may be a piece.

- The first and second members are juxtaposed in a direction in contact with the brake disc of the railway vehicle.

- The passage left at the interface of the first and second members is arranged in the middle part of the abutment zone.

- the butt area is substantially defined by the butting plane; The first and second members are of similar length along the length of the shoe holder and the through hole has a center defining an axis coincident with or spaced less than 5 mm from the butting plane.

- The friction set includes a pneumatic joint ring installed in the pneumatic conduit forming a pneumatic guide between the through hole of the shoe holder and the pneumatic conduit.

- The pneumatic joint ring includes a flange and a cylindrical part that rests on the bottom of the receiving slideway.

- The height of the cylindrical part is equal to the height of the dovetail profile shape.

According to the present invention, finally, a friction set for a railway disc brake system for a railway vehicle moving in one direction or two directions can be provided, characterized in that the friction set includes the following configuration.

It should be noted that the features of a friction set comprising a pneumatic connector and a friction set comprising a mating ring can of course be combined.

As a non-limiting example, four embodiments of the present invention are described with reference to the accompanying drawings.
1 is a perspective view of a railway disc brake system according to the present invention.
2 is a perspective view of two friction sets according to the present invention;
3 is a cross-sectional view of the friction set along a plane perpendicular to the longitudinal axis of the friction shoe.
4 is a plan view of a friction set;
5 is an exploded plan view of the friction set.
6 is a perspective view of a pneumatic joint ring according to the present invention.
7 is a cross-sectional view of a friction set according to a second embodiment of the invention, along a plane perpendicular to the longitudinal axis of the friction shoe.
8 is a plan view of a friction set according to a second embodiment.
9 is a cross-sectional view of a friction shoe of a friction set according to a second embodiment, along a plane perpendicular to the longitudinal axis of the friction shoe.
10 is a cross-sectional view of a friction set according to a third embodiment of the present invention, along a plane perpendicular to the longitudinal axis of the friction shoe.
11 is a plan view of a friction set according to a fourth embodiment of the present invention.

1 shows part of a railway vehicle 10 comprising a railway disc brake system 12 according to the invention. In this embodiment, the railroad car 10 is a train. It should be noted that the present invention may be implemented in any type of railroad car 10 . Thus, the rolling stock can be a metro light rail or even a streetcar. Similarly, the railroad car 10 may be a locomotive or a passenger car.

The railway vehicle 10 includes an axle 14 comprising a main shaft A1, a disk DK and wheels 18. A wheel 18 is placed on a rail 20 that is relatively movable by rotation about a main axis A1. Axle 14, disk DK and wheel 18 are fixed so that axle 14 can transmit rotational motion around main shaft A1 to disk DK and wheel 18. The railroad car 10 moves in two directions. Thus, the wheel 18 can move on the rail 20 in two directions opposite to each other (see S1 and S2 in FIG. 2 ).

In addition, the railway disc brake system 12 applies pressure to the disc DK to brake the rotation of the wheel 18 around the main shaft A1 and consequently to brake the movement of the railway vehicle 10 on the rail 20. there is. For this purpose, the railway disc brake system 12 comprises two friction sets 16 arranged on either side of the disc DK. These two friction sets 16 may be actuated by hydraulic or pneumatic actuators to symmetrically apply a braking force to the disc DK. In particular, Figure 2 shows the arrangement of the two friction sets 16 on either side of the disk DK, shown in dashed lines.

Thus, as shown in particular in FIGS. 2 to 4 , each friction set 16 of the railway disc brake system 12 has a longitudinal axis Z2 shown in FIG. 1 , which is tangential to the disc DK. Consistent with (T), it includes a shoe holder (3) supporting the friction shoe (22). The friction shoe 22 is intended to make direct contact with the disk DK.

3 and 4, each friction assembly 16 includes an axis called a transverse axis (X) and a vertical axis (Y). where Y is perpendicular to the friction plane.

The shoe holder 3 comprises a means 24 for attaching to the body of the railroad car 10 at the upper end of the shoe holder as shown in FIG. 2 . These attachment means 24 are in the form of two through-holes disposed opposite each other, forming respective axes X1 and X2 for receiving complementary attachment means supported by the body of the railcar 10. do. Axes X1 and X2 are perpendicular to axis A1 and axis Z2. The axes X1 and X2 are in the example shown substantially parallel to the direction of movement of the rolling stock on the rails.

The shoe holder 3 also includes a receiving slideway 4 that extends over the entire length of the shoe holder 3 in the longitudinal direction and functions to accommodate the friction shoe 22 . As shown in Fig. 5, the receiving slideway 4 is blocked. In this way, the receiving chute has one closed end 41 and one open end 40 . The function of open end 40 is to form an opening for extraction and insertion of friction shoe 22 . To position the friction shoe 22 on the receiving chute 4, the shoe holder 3 takes the shape of the slender member 19 and closes the open end 40 of the receiving chute 4 to the receiving chute. It further includes a movable locking member 19 substantially perpendicular to the furnace 4 . A movable locking member 19 may be secured to the friction shoe 3 to trap the friction shoe 22 within the receiving chute 4 . The movable locking member 19 can be seen as a solid pin in one of the branches received in a complementary concave groove disposed in the shoe holder 3 .

In addition, the shoe holder 3 includes a through hole 38 disposed substantially in the center of the receiving slideway 4 . The through hole 38 has a center defining a major axis A8 parallel to the vertical axis Y of the friction set 16 . The main axis A8 is also perpendicular to the main plane XY of the shoe holder 3. This axis is also orthogonal to the main plane of the through hole 38 .

As can be seen in Fig. 3, the friction shoe 22 includes a brake pad 7 which functions to contact the disk DK. Thus, the friction shoe comprises a first surface 71 intended for direct contact with the disc DK. The friction shoe 22 also includes a dovetail profile shape 6 that extends away from the brake pad. Here, the profile shape is a dovetail profile shape 6, which means that the cross section is trapezoidal and is complementary to the profile of the receiving slide 4 of the shoe holder 3. Accordingly, the dovetail profile shape 6 is configured to slide into the receiving chute 4 of the shoe holder 3 . Accordingly, the friction shoe 3 includes a second surface 72 opposite the first surface 71 , which directly contacts the bottom of the shoe holder 3 . It should be noted that according to the invention, the profile shape can have a quadrilateral-shaped cross-section. More generally, the cross-section of a profile shape can be any kind of shape.

In the example shown, the dovetail profile shape 6 comprises a longitudinal groove 68 extending the entire length of the dovetail profile shape 6 . The dovetail profile shape 6 can be obtained by cutting to the required length from an extruded metal profile shape. The material used may be stainless steel or high performance aluminum alloy.

Also, as particularly shown in FIG. 4 , the friction shoe 22 includes a first member 1 and a second member 2 each forming one half of the friction shoe 22 . More generally, they have similar lengths, at least along the longitudinal axis Z2. They are configured to slide one after another within the receiving slideway 4 . Accordingly, they are juxtaposed in contact with each other in the tangential direction T of the disk DK shown in FIG. 5, as can be seen by overlapping FIGS. 1 and 5. The contact between the first member and the second member is made near the butting area, which is a butting plane P as shown in FIG. 4 .

Further, as shown in FIG. 5 , the first member 1 has a semicircular recess (extending over the entire thickness of the first member 1) at its longitudinal end facing the second member 2 when viewed from above. 11). Similarly, the second member 2 comprises a semi-circular recess 12 at its longitudinal end towards the first member 1 , the dimensions of which are the recess 11 of the first member 1 . ) is the same as the dimension Thus, in the region of the butting plane P between the first and second members, the first and second members leave a passage formed by the two recesses 11 and 12 of the first and second members, respectively. . This passage is disposed in the middle part of the butting plane P, especially along the transverse direction X. As shown in FIG. 3, this passage is defined by a first space E1 defined by the face 71 of the friction shoe 22 and a second space defined by the face 72 of the friction shoe 22 ( E2) form a pneumatic conduit (9) making a fluid connection between them. A through hole 38 provided in the shoe holder 3 is located on the opposite side of the pneumatic conduit 9 . The major axis A8 of the through hole 38 lies within the butting plane P. More generally, the axis A8 of the through hole 38 is coincident with or separate from the butting plane P, or spaced less than 5 mm from the butting plane. Thus, the through hole 38 and the pneumatic conduit 9 form a continuous pneumatic circuit.

The friction set 16 also includes a pneumatic abutment ring 8 , shown in particular in FIG. 6 . The pneumatic joining ring 8 comprises a flange 81 extending annularly transverse to the axis A8. From the inside of this flange 81 extends a conical part, here a cylindrical part 82 . It should be further noted that the part may be of any kind of shape, in particular of any shape. As shown in FIG. 3 , the pneumatic joint ring 8 is positioned on the pneumatic conduit 9 such that the flange 81 rests on the bottom of the receiving slideway 4 . The flange 81 is in direct contact with the face 72 of the friction shoe 22 . The cylindrical part 82 of the pneumatic joint ring 8 extends from the inner wall of the pneumatic conduit 9 formed by the recesses 11, 12 of the first and second members made free of play, i.e. free from pneumatic leaks. do. 3, the height of the cylindrical portion 82 is equal to the height of the dovetail profile shape 6 of the friction shoe 22. It should also be noted that the height of the cylindrical portion 82 is equal to the height of the longitudinal groove 68 .

In this way, the pneumatic joint ring 8 forms a pneumatic guide between the through hole 38 of the shoe holder 3 and the pneumatic conduit 9 of the friction shoe 22 . In fact, most of the air flow flowing vertically downward from the space E1 into the pneumatic conduit 9 can reach the through hole 38 . In practice, the pneumatic joint ring 8 leaks along direction X in the gap located between the face 72 of the friction shoe 22 and the bottom of the receiving chute 4 in direct contact with the face 72. limit

The friction set 16 further includes a first connector 42 disposed inside the through hole 38 of the shoe holder 3 . The first connector 42 includes a first member 44 attached to a second member 46 . This attachment may in particular be attachment by means of screws or clippings. The first member 44 extends partially beyond the through hole 38 away from the friction shoe 22 , while the second member 46 is disposed in the through hole 38 . The friction set 16 includes a flexible hose 50 connected to the first connector 42 . To this end, the flexible hose 50 is connected to the first member 44 of the first connector 42 . The flexible hose 50 thus extends away from the friction shoe 22 . It should be noted that according to this embodiment, the first connector 42 may be formed as a single unit. In this case, the first member 44 and the second member 46 are made of one piece.

In this way, the friction set 16 comprises a pneumatic circuit comprising a pneumatic conduit 9 , a pneumatic joining ring 8 , a first connector 42 and a flexible hose 50 . The flexible hose 50 is advantageously connected to a recovery tank for particles arising from braking. In addition, the friction set 16 includes a pump capable of generating a reduced pressure in the aforementioned pneumatic circuit, in particular in the through hole 38, and a filtering element for capturing sucked particles.

Hereinafter, recovery of particles generated due to braking of the railroad car 10 will be described.

When the railway disc brake system 12 is operated, the actuator is pressed so that the brake pad 7 of the friction shoe 22 of each of the two friction sets 16 is in direct contact with the disc DK. As a result, due to the friction between the rotating disk DK and the brake pad 7, particles generated in braking by the brake pad 7 are released into the space E1.

At the same time, reduced pressure is created in the pneumatic circuit formed by the pneumatic conduit 9 , the pneumatic joint ring 8 , the first connector 42 and the flexible hose 50 .

The reduced pressure may be created near or remote from the brake system by a pump, for example a vacuum pump or a venturi system.

Thus, particles emerging from braking initially in space E1 reach the pneumatic conduit 9 . Thus, the particles reach the pneumatic joint ring 8, the first connector 42 and the flexible hose 50 to reach the tank for retrieval of the brake particles. As described above, the pneumatic joint ring 8 prevents the braking particles from reaching the gap disposed between the face 72 of the friction shoe 22 and the bottom of the receiving slideway 4 in direct contact with the face 72. prevent that A significant amount of particles from braking are recovered. The friction set according to the invention is therefore less prone to contamination.

The remaining three other embodiments of the present invention will be described with reference to FIGS. 7 to 11 below. Only differences from the first embodiment will be explicitly described. Reference numerals for identical objects are used as they are.

According to the second embodiment shown in FIGS. 7 to 9 , the dovetail profile structure 6 of the brake pad 7 does not include the longitudinal groove 68 shown in FIG. 3 .

According to the third embodiment shown in Fig. 10, the friction shoe 22 may be unitary.

A friction set 16 according to a fourth embodiment of the invention is shown in FIG. 11 . The friction set 16 comprises a pneumatic connector 5 mounted to the first member 44 of the first connector 42 . Adjustment of the position of the pneumatic connector 5 relative to the first member 44 is performed by screwing or clipping. The pneumatic connector 5 is thus mounted on the shoe holder 3 and extends away from the friction shoe 7 .

Thus, the pneumatic connector 5 is pneumatically connected with both the through hole 38 disposed in the shoe holder 3 and the flexible hose 50 . A flexible hose (50) extends away from the friction shoe (22) relative to the pneumatic connector (5). Further, the pneumatic connector 5 is rotated around an axis A8 as described above, perpendicular to the main plane XY of the shoe holder 3, as shown by the arrows arranged near the pneumatic connector 5. It is rotatable relative to the shoe holder 3 and the friction shoe 22.

Thus, the pneumatic connector 5 is more easily integrated into the structure of the railway vehicle 10 . In practice, flexible hose 50 can be oriented about axis A8.

It should be noted that features of the various embodiments of the present invention may be combined with each other to the extent that they are not compatible with each other.

Also, many modifications may be made to the present invention without departing from its scope.

In particular, the friction shoe 22 may include a plurality of members 1, 2. For example, the friction shoe 22 may include three or four members 1, 2.

Similarly, the shoe holder 3 may not be a unitary body, but may include a plurality of separate members.

The shoe holder 3 may include at least two through holes 38 .

Claims (10)

A friction set (16) for a railway disc brake system (12) of a railway vehicle (10) moving (S1, S2) in one or two directions, said friction set (16) comprising:
- a shoe holder (3) comprising an accommodating slideway (4);
- a friction shoe (22) comprising a brake pad (7) and a profile shape (6) configured to slide into the receiving slide (4), said friction shoe (22) having a first face (71) of the friction shoe (22). A friction shoe (including a pneumatic conduit 9 connecting a first space E1 partitioned by ) to a second space E2 partitioned by a second surface 72 opposite the friction shoe 22. 22);
- at least one through hole (38) arranged in the shoe holder (3) and directed towards the pneumatic conduit (9); and
- a pneumatic joint ring (8) disposed within the pneumatic conduit (9) forming a pneumatic guide between the through hole (38) of the shoe holder (3) and the pneumatic conduit (9) of the friction shoe (22); Characteristic friction set. According to claim 1,
The friction set, characterized in that the pneumatic joint ring (8) comprises a part with a flange (81) and a cylinder (82) resting on the bottom of the receiving slideway (4). According to claim 2,
The friction set, characterized in that the part has a cylindrical shape (82) and a height equal to the profile shape (6). According to claim 1 or 2,
One side of the accommodating slideway 4 of the shoe holder 3 is blocked, specifically one closed end 41 and one open end 40 forming an opening for extraction and insertion of the friction shoe 22 and characterized in that the friction set further comprises a detachable member (19) for fixing the friction shoe (22) on the receiving slide (4). According to claim 1 or 2,
The friction shoe 22 includes a first member 1 and a second member 2, the first member 1 and the second member 2 comprising the first member 1 and the second member 2 ), while forming a passage to form a pneumatic conduit (9) between the first member (1) and the second member (2) are configured to slide within the receiving slideway (4) until they come into contact with each other in the abutting area. A friction set, characterized in that. According to claim 5,
A friction set, characterized in that each of the first member (1) and the second member (2) forms one half of the friction shoe (22). According to claim 5,
A friction set, characterized in that the first member (1) and the second member (2) are juxtaposed in the tangential direction (T) of the brake disk (DK) of the railway vehicle (10). According to claim 5,
A friction set, characterized in that the passage left at the interface of the first member (1) and the second member (2) is arranged in the middle part of the abutment zone. According to claim 5,
The butting area is defined as the butting plane P, the lengths of the first member 1 and the second member 2 are similar to the length of the shoe holder 3 in the longitudinal direction Z2, and the through hole 38 is A friction set characterized in that it has a center defining an axis (A8) coinciding with the butting plane (P). A disk (DK) fixed to an axle (14) or a wheel (18) and two friction sets (16) according to claim 1 or 2 arranged on either side of the disk (DK). A railway disc brake system (12) for a railway vehicle (10) traveling in one direction or two directions (S1, S2).

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